Neuron–microglia contact-dependent mechanisms attenuate methamphetamine-induced microglia reactivity and enhance neuronal plasticity

Exposure to methamphetamine (Meth) has been classically associated with damage to neuronal terminals. However, it is now becoming clear that addiction may also result from the interplay between glial cells and neurons. Recently, we demonstrated that binge Meth administration promotes microgliosis an...

Full description

Saved in:
Bibliographic Details
Published inCells (Basel, Switzerland) Vol. 11 (3); no. 3; pp. 1 - 17
Main Authors Bravo, Joana, Ribeiro, Inês, Terceiro, Ana Filipa, Bonifácio Andrade, Elva, Portugal, Camila Cabral, Lopes, Igor M., Azevedo, Maria M., Sousa, Mafalda, Lopes, Cátia D. F., Lobo, Andrea C., Canedo, Teresa, Relvas, João Bettencourt, Summavielle, Teresa
Format Journal Article
LanguageEnglish
Published Switzerland MDPI 21.01.2022
MDPI AG
Subjects
Addictions
Alzheimer's disease
Animal cognition
Arginase
Astrocytes
Calcium
CD200
CD200 antigen
Cell culture
Cognitive ability
contact-dependent
Cytokines
Dopamine
Embryos
Glial cells
Inflammation
Kinases
Localization
Methamphetamine
Methamphetamine - metabolism
Methamphetamine - pharmacology
Microglia
Microglia - metabolism
Neural plasticity
Neuroglia - metabolism
neuron-to-microglia
Neuronal Plasticity - physiology
Neuronal-glial interactions
Neurons
Neurons - metabolism
Neuroprotection
Oxidative stress
PSD95
Tumor necrosis factor
St Louis Missouri
United States > US
neuron-to-microglia
contact-dependent
PSD95
methamphetamine
neuroprotection
CD200
Online AccessGet full text

Cover

More Information
Summary:Exposure to methamphetamine (Meth) has been classically associated with damage to neuronal terminals. However, it is now becoming clear that addiction may also result from the interplay between glial cells and neurons. Recently, we demonstrated that binge Meth administration promotes microgliosis and microglia pro-inflammation via astrocytic glutamate release in a TNF/IP3R2-Ca2+-dependent manner. Here, we investigated the contribution of neuronal cells to this process. As the crosstalk between microglia and neurons may occur by contact-dependent and/or contact-independent mechanisms, we developed co-cultures of primary neurons and microglia in microfluidic devices to investigate how their interaction affects Meth-induced microglia activation. Our results show that neurons exposed to Meth do not activate microglia in a cell-autonomous way but require astrocyte mediation. Importantly, we found that neurons can partially prevent Meth-induced microglia activation via astrocytes, which seems to be achieved by increasing arginase 1 expression and strengthening the CD200/CD200r pathway. We also observed an increase in synaptic individual area, as determined by co-localization of pre- and post-synaptic markers. The present study provides evidence that contact-dependent mechanisms between neurons and microglia can attenuate pro-inflammatory events such as Meth-induced microglia activation.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:2073-4409
2073-4409
DOI:10.3390/cells11030355